Hello everyone! Welcome to advanced neurobiology!
Neuroscience is a wonderful branch of science on how our brain perceives the external world, how our brain thinks, how our brain responds to the outside of the world, and how during disease or aging the neuronal connections deteriorate. We’re trying to understand the molecular, cellular nature and the circuitry arrangement of how nervous system works.
Through this course, you'll have a comprehensive understanding of basic neuroanatomy, electral signal transduction, movement and several diseases in the nervous system.
This advanced neurobiology course is composed of 2 parts (Advanced neurobiology I and Advanced neurobiology II, and the latter will be online later). They are related to each other on the content but separate on scoring and certification, so you can choose either or both. It’s recommended that you take them sequentially and it’s great if you’ve already acquired a basic understanding of biology.
Thank you for joining us!

Enseigné par

Yan Zhang

Professor

Yulong Li

Research Fellow

Transcription

And as was said, the pathological hall markers of this disease is one neurofibrillary tangle inside the cell and the other one is amyloid plaque or in another way called senile plaque. So because there are three pathological hall-markers of this disease, then we have three major hypotheses in this disease. The Tau hypothesis states the Tau mutation is the cause, is the original cause of the disease and then the other symptom, neuronal loss and then deposition of amyloidal beta are both the consequence of this Tau mutation. And then A-beta hypothesis stating the A-beta is the primary cause of the disease and then the aggravation of tau and the neural loss are the consequence of A-beta aggregation. And then we have a cell death hypothesis. Cell death hypothesis says that synaptic and neuronal loss is the primary cause of the disease and then the aggregation of tau and A-beta are the consequence of synaptic and neuron loss. So let's look at the A-beta hypothesis more closely. So this is in the senile plaque or called amyloid plaque and then these are the small molecule of amyloid beta to form these big aggregates. So the senile plaques are extracellular aggregates of this amyloid peptide. Besides humans, the senile plaque, the SP are also found in some chimpanzees, dogs, cats, and the polar bear. I always wonder how this study [LAUGH] was done on polar bears. The common rats or mice we used in our lab, they do not naturally have accumulation of amyloid with age. The precursor protein, amyloid beta, amyloid precursor protein, is a single transmembrane protein. It has several isoforms and in the brain, the most common isoform is APP695. So this protein normally under physiological conditions is highly expressed in our neurons and in brain region. And it get modified, it get synthesized in yar and modified in Golgi and its final destination is the cell membrane and it can be located either in cell body or in axon. And then, we still don't quite understand the normal function or physiological function of this protein. Why our neuron axon cells produce so much of APP, every day. There is some evidence suggest this protein can have function, or can have a role in neuron upgrowth and extension. Axon guidance and probably is synaptic transmission and maintenance of the axon. The phenotype of these mice are quite mild. So this is this protein. The great part is a transmembering domain and then the N terminus towards the extracellular parts and the C terminus towards the intercellular part. And what we see, the amyloid beta peptide is the green part here, it's when this protein get cut, get cleaved by both beta-secretase and gamma-secretase here, and then produce this fragment with around 40 amino acids. So normally, this protein is not cut by beta and gamma secretase. Normally, it is processed by so-called alpha secretase. The size of alpha secretase cleavage is right in the middle of this peptide. If this precursor protein is cut by alpha secretase around here, it will not cause Alzheimer's disease. If it cut by beta and gamma secretase, produces A-beta and then it has a potential to induce Alzheimer's disease. It doesn't mean if you have this peptide, this A-beta, you are doomed to have Alzheimer's disease. Like in normally aged person's brain, we still have huge amount of this A-beta peptide, and we don't understand why. We have this peptide, and some people can have the disease and some people don't. So the beta and the gamma secretase are the two secretases to produce A-beta peptide, and then for the gamma secretase. Gamma secretase is not a single protein, it forms a complex by presenilin 1, Nicastrim, Aph-1, and Pen-2 to cut inside of the membrane. So if you look at this gamma secretase site, its very conspicuous because it cut inside of the cell membrane and then we know for most enzyme to have a cleavage, they need to be in the water phase because they need water molecule into the complex. But this complex, this enzyme complex located right inside of the cell membrane. So this is a diagram showing the structure, the rough structure of a prison 91, the major component of gamma secretase complex. Its a protein with metabole transmembrane domain. And then with both intermix and then towards the cytosol region. And then the yellow part here are suggested to have the enzyme activity and somatic activity.